AFLplusplus/llvm_mode/MarkNodes.cc

#include <algorithm>
#include <map>
#include <queue>
#include <set>
#include <vector>
#include "llvm/ADT/DenseMap.h"
#include "llvm/ADT/DenseSet.h"
#include "llvm/ADT/SmallVector.h"
#include "llvm/IR/BasicBlock.h"
#include "llvm/IR/CFG.h"
#include "llvm/IR/Constants.h"
#include "llvm/IR/Function.h"
#include "llvm/IR/IRBuilder.h"
#include "llvm/IR/Instructions.h"
#include "llvm/IR/Module.h"
#include "llvm/Pass.h"
#include "llvm/Support/Debug.h"
#include "llvm/Support/raw_ostream.h"

using namespace llvm;

DenseMap<BasicBlock *, uint32_t> LMap;
std::vector<BasicBlock *> Blocks;
std::set<uint32_t> Marked , Markabove;
std::vector< std::vector<uint32_t> > Succs , Preds;

void reset(){
  LMap.clear();
  Blocks.clear();
  Marked.clear();
  Markabove.clear();
}

uint32_t start_point;

void labelEachBlock(Function *F) {
  // Fake single endpoint;
  LMap[NULL] = Blocks.size();
  Blocks.push_back(NULL);
 
  // Assign the unique LabelID to each block;
  for (auto I = F->begin(), E = F->end(); I != E; ++I) {
    BasicBlock *BB = &*I;
    LMap[BB] = Blocks.size();
    Blocks.push_back(BB);
  }
  
  start_point = LMap[&F->getEntryBlock()];
}

void buildCFG(Function *F) {
  Succs.resize( Blocks.size() );
  Preds.resize( Blocks.size() );
  for( size_t i = 0 ; i < Succs.size() ; i ++ ){
    Succs[ i ].clear();
    Preds[ i ].clear();
  }

  //uint32_t FakeID = 0;
  for (auto S = F->begin(), E = F->end(); S != E; ++S) {
    BasicBlock *BB = &*S;
    uint32_t MyID = LMap[BB];
    //if (succ_begin(BB) == succ_end(BB)) {
      //Succs[MyID].push_back(FakeID);
      //Marked.insert(MyID);
    //}
    for (auto I = succ_begin(BB), E = succ_end(BB); I != E; ++I) {
      Succs[MyID].push_back(LMap[*I]);
    }
  }
}

std::vector< std::vector<uint32_t> > tSuccs;
std::vector<bool> tag , indfs;

void DFStree(size_t now_id) {
  if(tag[now_id]) return;
  tag[now_id]=true;
  indfs[now_id]=true;
  for (auto succ: tSuccs[now_id]) {
    if(tag[succ] and indfs[succ]) {
      Marked.insert(succ);
      Markabove.insert(succ);
      continue;
    }
    Succs[now_id].push_back(succ);
    Preds[succ].push_back(now_id);
    DFStree(succ);
  }
  indfs[now_id]=false;
}
void turnCFGintoDAG(Function *F) {
  tSuccs = Succs;
  tag.resize(Blocks.size());
  indfs.resize(Blocks.size());
  for (size_t i = 0; i < Blocks.size(); ++ i) {
    Succs[i].clear();
    tag[i]=false;
    indfs[i]=false;
  }
  DFStree(start_point);
  for (size_t i = 0; i < Blocks.size(); ++ i) 
    if( Succs[i].empty() ){
      Succs[i].push_back(0);
      Preds[0].push_back(i);
    }
}

uint32_t timeStamp;
namespace DominatorTree{
  std::vector< std::vector<uint32_t> > cov;
  std::vector<uint32_t> dfn, nfd, par, sdom, idom, mom, mn;

  bool Compare(uint32_t u, uint32_t v) {
    return dfn[u] < dfn[v];
  }
  uint32_t eval(uint32_t u) {
    if( mom[u] == u ) return u;
    uint32_t res = eval( mom[u] );
    if(Compare(sdom[mn[mom[u]]] , sdom[mn[u]])) {
      mn[u] = mn[mom[u]];
    }
    return mom[u] = res;
  }

  void DFS(uint32_t now) {
    timeStamp += 1;
    dfn[now] = timeStamp;
    nfd[timeStamp - 1] = now;
    for( auto succ : Succs[now] ) {
      if( dfn[succ] == 0 ) {
        par[succ] = now;
        DFS(succ);
      }
    }
  }

  void DominatorTree(Function *F) {
    if( Blocks.empty() ) return;
    uint32_t s = start_point;

    // Initialization
    mn.resize(Blocks.size());
    cov.resize(Blocks.size());
    dfn.resize(Blocks.size());
    nfd.resize(Blocks.size());
    par.resize(Blocks.size());
    mom.resize(Blocks.size());
    sdom.resize(Blocks.size());
    idom.resize(Blocks.size());

    for( uint32_t i = 0 ; i < Blocks.size() ; i ++ ) {
      dfn[i] = 0;
      nfd[i] = Blocks.size();
      cov[i].clear();
      idom[i] = mom[i] = mn[i] = sdom[i] = i;
    }

    timeStamp = 0;
    DFS(s);

    for( uint32_t i = Blocks.size() - 1 ; i >= 1u ; i -- ) {
      uint32_t now = nfd[i];
      if( now == Blocks.size() ) {
        continue;
      }
      for( uint32_t pre : Preds[ now ] ) {
        if( dfn[ pre ] ) {
          eval(pre);
          if( Compare(sdom[mn[pre]], sdom[now]) ) {
            sdom[now] = sdom[mn[pre]];
          }
        }
      }
      cov[sdom[now]].push_back(now);
      mom[now] = par[now];
      for( uint32_t x : cov[par[now]] ) {
        eval(x);
        if( Compare(sdom[mn[x]], par[now]) ) {
          idom[x] = mn[x];
        } else {
          idom[x] = par[now];
        }
      }
    }

    for( uint32_t i = 1 ; i < Blocks.size() ; i += 1 ) {
      uint32_t now = nfd[i];
      if( now == Blocks.size() ) {
        continue;
      }
      if(idom[now] != sdom[now])
        idom[now] = idom[idom[now]];
    }
  }
}; // End of DominatorTree

std::vector<uint32_t> Visited, InStack;
std::vector<uint32_t> TopoOrder, InDeg;
std::vector< std::vector<uint32_t> > t_Succ , t_Pred;

void Go(uint32_t now, uint32_t tt) {
  if( now == tt ) return;
  Visited[now] = InStack[now] = timeStamp;

  for(uint32_t nxt : Succs[now]) {
    if(Visited[nxt] == timeStamp and InStack[nxt] == timeStamp) {
      Marked.insert(nxt);
    }
    t_Succ[now].push_back(nxt);
    t_Pred[nxt].push_back(now);
    InDeg[nxt] += 1;
    if(Visited[nxt] == timeStamp) {
      continue;
    }
    Go(nxt, tt);
  }

  InStack[now] = 0;
}

void TopologicalSort(uint32_t ss, uint32_t tt) {
  timeStamp += 1;

  Go(ss, tt);

  TopoOrder.clear();
  std::queue<uint32_t> wait;
  wait.push(ss);
  while( not wait.empty() ) {
    uint32_t now = wait.front(); wait.pop();
    TopoOrder.push_back(now);
    for(uint32_t nxt : t_Succ[now]) {
      InDeg[nxt] -= 1;
      if(InDeg[nxt] == 0u) {
        wait.push(nxt);
      }
    }
  }
}

std::vector< std::set<uint32_t> > NextMarked;
bool Indistinguish(uint32_t node1, uint32_t node2) {
  if(NextMarked[node1].size() > NextMarked[node2].size()){
    uint32_t _swap = node1;
    node1 = node2;
    node2 = _swap;
  }
  for(uint32_t x : NextMarked[node1]) {
    if( NextMarked[node2].find(x) != NextMarked[node2].end() ) {
      return true;
    }
  }
  return false;
}

void MakeUniq(uint32_t now) {
  bool StopFlag = false;
  if (Marked.find(now) == Marked.end()) {
    for(uint32_t pred1 : t_Pred[now]) {
      for(uint32_t pred2 : t_Pred[now]) {
        if(pred1 == pred2) continue;
        if(Indistinguish(pred1, pred2)) {
          Marked.insert(now);
          StopFlag = true;
          break;
        }
      }
      if (StopFlag) {
        break;
      }
    }
  }
  if(Marked.find(now) != Marked.end()) {
    NextMarked[now].insert(now);
  } else {
    for(uint32_t pred : t_Pred[now]) {
      for(uint32_t x : NextMarked[pred]) {
        NextMarked[now].insert(x);
      }
    }
  }
}

void MarkSubGraph(uint32_t ss, uint32_t tt) {
  TopologicalSort(ss, tt);
  if(TopoOrder.empty()) return;

  for(uint32_t i : TopoOrder) {
    NextMarked[i].clear();
  }

  NextMarked[TopoOrder[0]].insert(TopoOrder[0]);
  for(uint32_t i = 1 ; i < TopoOrder.size() ; i += 1) {
    MakeUniq(TopoOrder[i]);
  }
}

void MarkVertice(Function *F) {
  uint32_t s = start_point;

  InDeg.resize(Blocks.size());
  Visited.resize(Blocks.size());
  InStack.resize(Blocks.size());
  t_Succ.resize(Blocks.size());
  t_Pred.resize(Blocks.size());
  NextMarked.resize(Blocks.size());

  for( uint32_t i = 0 ; i < Blocks.size() ; i += 1 ) {
    Visited[i] = InStack[i] = InDeg[i] = 0;
    t_Succ[i].clear();
    t_Pred[i].clear();
  }
  timeStamp = 0;
  uint32_t t = 0;
  //MarkSubGraph(s, t);
  //return;

  while( s != t ) {
    MarkSubGraph(DominatorTree::idom[t], t);
    t = DominatorTree::idom[t];
  }

}

// return {marked nodes}
std::pair<std::vector<BasicBlock *>,
          std::vector<BasicBlock *> >markNodes(Function *F) {
  assert(F->size() > 0 && "Function can not be empty");

  reset();
  labelEachBlock(F);
  buildCFG(F);
  turnCFGintoDAG(F);
  DominatorTree::DominatorTree(F);
  MarkVertice(F);

  std::vector<BasicBlock *> Result , ResultAbove;
  for( uint32_t x : Markabove ) {
    auto it = Marked.find( x );
    if( it != Marked.end() )
      Marked.erase( it );
    if( x )
      ResultAbove.push_back(Blocks[x]);
  }
  for( uint32_t x : Marked ) {
    if (x == 0) {
      continue;
    } else {
      Result.push_back(Blocks[x]);
    }
  }

  return { Result , ResultAbove };
}